Systems and methods for creating excess funds from retail transactions and apportioning those funds into investments

ABSTRACT

A computer-implemented system comprising one or more processors for executing logic code for receiving transaction data to process a first transaction from a plurality of transactions is provided. The transaction data may include at least one of a transaction descriptor or a transaction value associated with the first transaction. The transaction data is filtered by applying a filtering parameter to at least one of the transaction descriptor or the transaction value. Application of a round up process to the first transaction is prevented based on the filtering, in response to the determining that the first transaction is not conducive to the round up process, thereby preventing an error state in execution of logic code by at least one processor configured for applying the round up process to the first transaction.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to and is a continuation of U.S. patent application Ser. No. 13/830,579, filed on Mar. 14, 2013, which claims priority to and is a continuation-in-part of U.S. patent application Ser. No. 13/366,499, filed on Feb. 6, 2012. The contents of said prior-filed applications are hereby incorporated by reference herein in their entirety. This application further incorporates the entire content of the following commonly owned applications by reference: U.S. patent application Ser. No. 14/329,509, filed on Jul. 11, 2014, U.S. patent application Ser. No. 15/676,423, filed on Aug. 14, 2017, and U.S. patent application Ser. No. 16/677,560, filed on Nov. 7, 2019.

TECHNICAL FIELD

The subject matter disclosed in this application relates generally to the field of creating and distributing investment funds, and more particularly to systems and methods for creating excess funds from consumer transactions and distributing those funds into one or more investment accounts.

BACKGROUND

It is well known that individuals must set up savings accounts retirement accounts and as early as possible. While some experts claim that a person will only need 70% of their pre-retirement pay after they retire, other studies have shown that retirees must save up to 126% of their ending salary to maintain their standard of living, factoring in inflation and medical cost increases. As of 2012, U.S. Census Bureau has estimated that the average life expectancy of an individual is 78.5 years, and that the average retirement age was 62 years of age, which means that a person must, on average, plan for 16.5 years of retirement. It is also known that the anticipated length of retirement will fluctuate with changes to social security funding, healthcare costs, the tax code, as well as concurrent medical advances increasing life expectancy.

Based on certain assumptions, Time Magazine conservatively estimates that a person whose household earnings were $75,000 a year would need $1,000,000.00 in savings (in today's dollars) if they retired at the age of 62. Other sources indicate that the amount could be twice-as-much or half-as-much, based on other assumptions. Irrespective of the final calculus, one common principle emerges: a person must set-aside a large nest egg in order to retire comfortably.

Toward that end, a variety of financial investment programs exist, such as long-term investment plans that allow the average person to save for their future.

Traditionally, these programs are set up by individuals and/or employers, and come in a number of forms, including deposit accounts, equities (e.g. stocks), debt securities (e.g. bonds), index and mutual funds, government securities (e.g. T-bills, etc.), insurance vehicles (e.g. term-life plans), and real estate investments (e.g., properties, REITs, etc.).

Retirement accounts set up by individuals are usually modest in size, scope, and return because of the investor's lack of sophistication. Moreover, even for the financially savvy, there is a lack of access to premium financial investments which are often complex, require substantial minimum investments, and necessitate regular management.

For this reason as well as others, many large institutions and employers have attempted to bridge the gap by providing umbrella programs, such as pension plans. Pension plans usually take the form of defined benefits programs (e.g. IRAs and 401(k) derived from a portion of the employee's income) and/or defined contributions programs (same as a defined benefits program, except that a portion of the investment is “matched” by the employer). Future payouts are based on the performance of the underlying investments.

When used correctly, these programs not only promote economic growth but also promote personal financial safety. Investing allows for economic expansion and market liquidity, while concurrently affording prospective gains for the investor. The most effective long-term investments are optimized to maximum return while controlling market fluctuation at acceptable risk thresholds. Many bear low risk while offering significant yields. As those of ordinary skill in the art would appreciate, methods for reducing investment risk are best explained in Modern Portfolio Theory (MPT) which include, but are not limited to, diversification and hedging strategies. These concepts are well understood and appreciated.

It is not uncommon for well-managed investments to earn double-digit returns, which are often significantly higher than afforded by a traditional bank account. For example, over the last 25 years, the average return of the Standard and Poor's 500 (S&P 500) was 10.6%, while the average bank interest rate was under 6%. And when one compensates for 3% inflation, investments have shown multiples higher return than ordinary deposit accounts

Unfortunately, despite the potential reward of investing with risk-aversion techniques, many individuals fail to establish any long-term investment plan. In some cases, these programs are not available to a large portion of the population. Even where available, many individuals lack the motivation to invest over a long period of time because it is difficult to visualize aggregate returns without sufficient investment expertise. Moreover, transactions costs (e.g., fees, commissions, and so on) are a deterrent.

Notwithstanding, the “retirement problem” for millions of people remain. Saving hundreds of thousands of dollars, or even millions of dollars in a retirement account—or ten to twenty times a person's annual salary—is generally seen as an unattainable amount of money. But the simple fact of the matter is that it is not. With disciplined saving starting at an early age, and average market returns, an individual need only set-aside approximately 15% of his or her income every pay-period.

But most individuals are not financially disciplined. Easy access to credit, widely-publicized tales of overnight riches and extravagant lifestyles, and irrational exuberance has conditioned most individuals to spend money rather than save it. With a credit card in hand, and a quick flick of the wrist, consumers are accustomed to the joyous instant gratification that follows. Indeed, over the last 20 years, the U.S. Federal Reserve has found that the average personal savings rate (i.e. the difference between spending and income) has fluctuated from a low of 1% to a high of 8%, with a long-term average of 6.9%. The shortfall can have disastrous consequences for a potential retiree.

Thus, in applicant's view, the problem is not challenging society-wide views of fiscal responsibility, but rather revising the manner that individuals perceive the savings and investing process. In other words, if saving is looked at as an expense with the potential for significant returns, rather than something that gets in the way of immediate spending, then an individual is far more likely to save.

One method for encouraging savings is to add a self-imposed “tax” during routine consumer transactions. For example, a current approach allows consumers to save and/or donate a portion of a credit or debit transaction. An example is disclosed in U.S. Pat. No. 6,112,191, to Burke, filed Apr. 27, 1995, for a “Method and System to Create and Distribute Excess Funds from Consumer Spending Transactions,” which is hereby incorporated by reference in its entirety. The system rounds up any credit or debit transaction to the nearest dollar and allows the consumer to save the difference between the actual transaction price and the rounded amount in a surplus account. This approach creates excess funds from spending transactions and provides an immediate opportunity to set aside these assets at the point of sale.

Although these systems are effective for creating opportunities to save, they are utterly lacking when it comes to facilitating actual long-term investing. Specifically, two additional problems remain:

First, current approaches only set aside the excess funds for future consumption (i.e., saved) rather than investing in hopes of realizing higher long-term returns. In other words, current systems only allow consumers to apportion funds for potential investment, but not actually invest those funds. Consumers must manually move funds between a surplus account and an investment account, pro-actively search for investment vehicles (i.e. researching their expected future return), decide upon tolerable risk profiles for their portfolio, and continuously manage those investments.

Second, current systems do not motivate long-term investment because future values are difficult to conceptualize in the abstract. Unless a consumer can visualize expected future returns (either with individual investments or a portfolio thereof), that consumer remains reluctant to invest surplus funds into productive assets. But current systems fail because they assume consumers possess adequate financial knowledge to enable them to realize long-term returns. Many investors, particularly the inexperienced, may not see the immediate benefit of saving. Without immediate knowledge of prospects for significant future returns, the opportunity to save alone may not overcome a pre-conceived reluctance to defer funds.

The compound effect of these two limitations undermine their intended purpose: motivating consumers to save for their future. In other words, techniques that only allow a consumer to save excess funds during a transaction rarely provides the consumer with potential investment benefits in real-time. Thus, even prior to considering investment options, current systems do not overcome a consumer's lack of motivation to save. Like a driver without a roadmap, current systems fail to provide direction to a desired destination.

Accordingly, an improved system and method for creating a nexus between savings/investments and accompanying consumer transactions is desirable.

SUMMARY

To improve upon existing systems, preferred embodiments of the present invention provide a system and method for creating excess funds from retail transactions and apportioning those funds into investments. One preferred system, for example, can include a consumer communication device (i.e. a user device) configured to read consumer transactions, either directly or indirectly, from one or more financial data sources, such as banking, credit card, investment data stores. The system may also include a central server to which the user device connects over a data network. The user device is operatively coupled to a computer program product, the computer program product having a computer-usable medium including a sequence of instructions which, when executed by a processor, causes said processor to execute a process that virtually round-up the user's transactions to the nearest dollar, execute a financial charge/transfer into a designated investment account when the virtual round-ups meet a minimum threshold, and provide the user with opportunities to invest those surplus funds into one or more predefined investment vehicles.

In addition, one preferred method for creating excess funds from retail transactions and apportioning those funds into investments can include queuing up surplus funds that rounds-up some or all of a consumer's transaction to the nearest dollar (Single Account Virtual Aggregation); transferring the aggregation of surplus funds into a surplus account when a defined threshold is met (Threshold Triggered Single User ACH); pooling all of the transfers from all system users such that they are invested into one or more investments (Batch User Aggregation For Investing). As described below, the preferred method can further include displaying a user's actual and pending round-ups, for review and further investment by the user (Scrolling Timeline of Round-ups). Other variations, features, and aspects of the system and method of the preferred embodiment are described in detail below with reference to the appended drawings.

An illustration of the invention is helpful at this point: Assume a user makes a single credit card purchase every day (say $4.15 on her morning coffee), the present invention will—based on the user's prior authorization—round up the transaction to $5.00, and account for the transaction in two categories: (1) a $4.15 charge on the user's credit-card; and (2) a $0.85 virtual charge to be made at a later date (i.e. it will be placed in the “Digital Queue”). Once all the virtual charges in the Digital Queue reaches a user-defined minimum threshold (say $5.00), then the invention will automatically charge the user $5.10 on the sixth day. This amount, as well as the amount for all other users of the invention, will be placed into an omnibus account (likely managed by the operators of the invention), and then periodically invested into one or more pre-defined investments (e.g., savings account, qualified index or mutual funds, etc.). Each user of the invention will receive his-own or her-own pro-rata share of the investment. Further, the user will have real-time access to each purchase made, their respective Digital Queue, past round-ups transferred into the investment account (both by transaction and aggregated transfers), as well as their individual investment portfolio.

The preferred embodiments of the present invention may also be used with a prepaid credit cards and/or Point of Sales (POS) terminal for consumer transactions. Because certain users have opted into alternate payment methods, such as contactless (e.g., radio) and direct (e.g., electrical conduction) transactions/data exchange methodologies, the instant invention may be readily adapted to conform to such. Such methodologies may include, for example, near field communication (NFC) device readers, credit/debit card readers, smart card readers, radio frequency identification (RFID) tag readers, and so on. Thus, the present invention could be used independently (by reading transactions from banks, credit card companies, or investment firms) or in the alternative, the present invention could also be interfaced with, and used in conjunction with, POS transactions. An example of such systems and methods is described in U.S. patent application Ser. No. 13/66,499, entitled “Systems And Methods For Managing Consumer Transaction-Based Investments,” to Cruttenden et al, which is hereby incorporated by reference in its entirety (“Cruttenden Application”).

Other systems, methods, features and advantages of the invention will be or will become apparent to one with skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description, be within the scope of the invention, and be protected by the accompanying claims.

BRIEF DESCRIPTION OF THE FIGURES

In order to better appreciate how the above-recited and other advantages and objects of the inventions are obtained, a more particular description of the embodiments briefly described above will be rendered by reference to specific embodiments thereof, which are illustrated in the accompanying drawings. It should be noted that the components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. Moreover, in the figures, like reference numerals designate corresponding parts throughout the different views. However, like parts do not always have like reference numerals. Moreover, all illustrations are intended to convey concepts, where relative sizes, shapes and other detailed attributes may be illustrated schematically rather than literally or precisely.

FIG. 1 is a schematic block diagram of a system used in connection with creating excess funds from retail transactions and apportioning those funds into investments in accordance with a preferred embodiment of the present invention.

FIG. 2 is an example the computerized screen of the benefits of the invention as explained to a prospective user as found on the preferred embodiment of present invention.

FIG. 3 is an example the computerized screen that explains the sign-up process as found on the preferred embodiment of present invention.

FIG. 4 is an example the computerized screen of step 1 of the sign up-process (i.e. linking a spending account to collect round-ups) as found on the preferred embodiment of present invention.

FIG. 5 is an example the computerized screen of step 2 of the sign up-process (i.e. setting up a funding source) as found on the preferred embodiment of present invention.

FIG. 6 is an example the computerized screen of step 3 of the sign up-process (i.e. setting up an investment account) as found on the preferred embodiment of present invention.

FIG. 7 is an example the computerized screen of a user's menu as found on the preferred embodiment of present invention.

FIG. 8 is an example the computerized screen of a user's home page as found on the preferred embodiment of present invention.

FIG. 9 is an example the computerized screen of a user's interface showing a summary of round-ups as found on the preferred embodiment of present invention.

FIG. 10 is an example the computerized screen of a user's interface showing a detailed information related to the round-ups as found on the preferred embodiment of present invention.

FIG. 11 is an example the computerized screen of a user's investments pages as found on the preferred embodiment of present invention.

FIG. 12 is an example the computerized screen of a user's estimated future value page as found on the preferred embodiment of present invention.

FIG. 13 is an example the computerized screen of a user's add-funds pages as found on the preferred embodiment of present invention.

FIG. 14 is an example the computerized screen of a user's withdraw-funds pages as found on the preferred embodiment of present invention.

FIG. 15 depicts an overall flowchart illustrating an exemplary embodiment of a method by which excess funds from retail transactions are apportioning into investments.

FIG. 16 depicts an overall flowchart illustrating an exemplary embodiment of a method for single account virtual aggregation and method for threshold triggered single user ACH.

FIG. 17 depicts an additional logic flowchart illustrating an exemplary embodiment of a method for single account virtual aggregation.

FIG. 18 depicts an additional logic flowchart illustrating an exemplary embodiment of a method for threshold triggered single user ACH.

FIG. 19 depicts a flowchart illustrating an exemplary embodiment of a method for pooling aggregations for omnibus investments.

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS

The following definitions are not intended to alter the plain and ordinary meaning of the terms below but are instead intended to aid the reader in explaining the inventive concepts below:

As used herein, the term “USER DEVICE” shall generally refer to a desktop computer, laptop computer, notebook computer, tablet computer, mobile device such as a smart phone or personal digital assistant, smart TV, gaming console, streaming video player, or any other, suitable networking device having a web browser and/or stand-alone application configured to interface with and/or receive any or all data to/from the CENTRAL COMPUTER and/or one or more components of the preferred system 10. The user device shall be considered in its broadest form, with any method of user input, including without limitation, touch, voice, gesture, vision, or other sensory user input.

As used herein, the term “CENTRAL COMPUTER” shall generally refer to one or more sub-components or machines configured for receiving, manipulating, configuring, analyzing, synthesizing, communicating, and/or processing data associated with the user, the user's bank information, the user's credit card information, and/or the user's investment information. Any of the foregoing subcomponents or machines can optionally be integrated into a single operating unit, or distributed throughout multiple hardware entities through networked or cloud-based resources. Moreover, the central computer may be configured to interface with and/or receive any or all data to/from the USER DEVICE and/or one or more components of the preferred system 10.

As used herein, the term “BANK DATA” shall generally refer to data acquired by data stores (including without limitation, through feeds, databases, or files containing data), related to the user, and that contain a user's banking information. Bank data may be furnished by a banking institution (such as Bank of America or Wells Fargo), the bank's designated data host, an authorized third-party data aggregator (such as Intuit or Yodlee), and/or the user himself/herself/itself. An example of bank data is a ledger of individual transactions in a bank account (including without limitation, deposit accounts, money market accounts, certificate of deposit accounts, and the like). Another example is the account data from credit unions (such as the Navy Federal Credit Union), savings and loan institutions, or other comparable financial institutions which offers banking services to consumers. These data stores are anticipated to contain numerous records related to a person's financial accounts, such as records of deposits, checks cashed, debit card transactions related to consumer purchases, and/or funds transferred. Bank data may further include personally identifying information such as social security numbers, driver's license number, and the like.

As used herein, the term “CREDIT CARD DATA” shall generally refer to data stores (including without limitation, through feeds, databases, or files containing data), related to the user, and that contain a user's borrowing and or credit account information. Credit card data may be furnished by a lending institution that offers revolving or prepaid credit in the form of a credit card (e.g. institutions that offer Visa, MasterCard, American Express, dinner's clubs, or retailer specific credit accounts, such as Macy's, Guitar Center, etc.), the lending institution's designated data host, an authorized third-party data aggregator (such as Intuit or Yodlee), and/or the user himself/herself/itself. These data stores are anticipated to contain numerous records related to a person's spending accounts, including without limitation, consumer purchases, interest expenses, fees, funds transfers, and outstanding balances. Credit card data may further include personally identifying information such as social security numbers, driver's license number, and the like.

As used herein, the term “INVESTMENT DATA” shall generally refer to data stores (including without limitation, through feeds, databases, or files containing data), related to the user, and that contain a user's investment information. Investment data may be furnished by an investing institution, the investing institution's designated data host, an authorized third-party data aggregator (such as Intuit or Yodlee), and/or the user himself/herself/itself. Investment institutions are contemplated in their broadest sense, and may include brokerage firms (e.g. J.P. Morgan or UBS), banks, insurance companies, retirement or pension funds, hedge funds, mutual funds, and/or domestic/foreign equivalents. Example of investment data generally include ledgers of individual transactions in an investment account. These data stores are anticipated to contain numerous records related to a person's investments, and may generally include information related to purchases and sales of financial securities, commodities, forex, and the like. Investment data may further include personally identifying information such as social security numbers, driver's license number, etc.

As used herein, the term “FINANCIAL DATASETS” shall generally refer to BANK DATA, CREDIT CARD DATA, and INVESTMENT DATA, individually, collectively, or in one or more combinations. Financial datasets preferably function to accumulate, store, maintain, and/or make available financial data relating to the user. Additionally, the financial datasets can include any information for any or all account holders on a user's banking, credit card, and investment accounts, thereby encompassing one or more degrees of separation between the user and the data extracted from the investment data (e.g., joint accounts, family trusts, corporations, etc.). The financial datasets may be available for free or at a cost through direct or indirect access to one or more institutions.

As used herein, the term “USER'S CREDENTIALS” shall generally refer to the user's data required to authenticate the user, in the USER DEVICE, CENTRAL COMPUTER, and/or to access external data stores, such as found in the FINANCIAL DATASETS. By way of example, these credentials may include the user's social security number, driver's license number, date of birth, financial institution specific usernames and passwords, pin numbers, and/or other information requested by the institution to authenticate the user.

As used herein, the term “NETWORK” shall generally refer to any suitable combination of the global Internet, a wide area network (WAN), a local area network (LAN), and/or a near field network, as well as any suitable networking software, firmware, hardware, routers, modems, cables, transceivers, antennas, and the like. Some or all of the components of the preferred system 10 can access the network through wired or wireless means, and using any suitable communication protocol/s, layers, addresses, types of media, application programming interface/s, and/or supporting communications hardware, firmware, and/or software.

As used herein and in the claims, the singular forms “a,” “an,” and “the” include plural references unless the context clearly dictates otherwise.

Unless defined otherwise, all technical and scientific terms used herein have the same meanings as commonly understood by one of ordinary skill in the art.

The following description of the preferred embodiments of the invention is not intended to limit the invention to these preferred embodiments, but rather to enable any person skilled in the art to make and use this invention. Although any methods, materials, and devices similar or equivalent to those described herein can be used in the practice or testing of embodiments, the preferred methods, materials, and devices are now described.

The present invention relates to improved methods and systems for creating excess funds from retail transactions and apportioning those funds into investments, which is most suitable for use with individuals, and shall be described as such throughout this document. Notwithstanding, the present invention may also be used by other types of entities including, but not limited to, corporations, companies, small businesses, and trusts, and/or any other recognized legal entities.

As shown in FIG. 1, a preferred operating environment for creating excess funds from retail transactions and apportioning those funds into investments in accordance with a preferred embodiment can generally include a USER DEVICE 40, a CENTRAL COMPUTER 50, a NETWORK 30, and one or more data sources, including for example BANK DATA 20, CREDIT CARD DATA 22, and INVESTMENT DATA 24 (i.e. the FINANCIAL DATASETS). In addition, the preferred system 10 can store information from the FINANCIAL DATASETS in one or more databases, including for example, INVESTMENT D/B 60 and ROUND-UPS D/B 70. These databases may be populated by manual input by the user or a system operator, or preferably by automated downloads from external data sources.

The preferred system 10 can include at least a CENTRAL COMPUTER 50 and/or a USER DEVICE 40, which (individually or collectively) function to provide users a continuous opportunity for saving and investment by (a) rounding up individual transactions to the nearest dollar; (b) placing those discrete savings into a Digital Queue; and (c) participating in qualified aggregate investments offered directly or indirectly through the invention, all based on a novel and unique set of processes and from a plurality of user choices. Moreover, the preferred system 10 functions to provide the user with real-time access to each consumer transaction made (whether past or present), past round-ups transferred into the investment account (both by transaction and aggregated transfers), their respective Digital Queue for future investment, as well as investment portfolio based on the novel and unique methodology described below.

In other words, this invention relates to the preferred methodology for creating excess funds from retail transactions and apportioning those funds into investments that takes place within the CENTRAL COMPUTER 50 and/or a USER DEVICE 40, after all FINANCIAL DATASETS are temporarily gathered or otherwise downloaded from the CENTRAL COMPUTER 50, USER DEVICE 40, and/or one or more data sources, including for example BORROWER'S DATA 13, BANK DATA 20, CREDIT CARD DATA 22, and INVESTMENT DATA 24.

FIG. 2 is an example of the initial computerized screens (user interfaces) as found on the preferred embodiment of present invention, wherein a new user is given a brief tutorial of the benefits of the invention. Color of action buttons change from blue to green when all required fields are appropriately completed (not shown). Returning users may bypass this initial sequence, and simply enter a user name (email), password, and/or four-digit passcode (not shown). The preferred embodiment of the present invention, may further include a screen requiring the user to agree to terms and conditions before signing up (placeholder shown).

FIG. 3 is an example of the computerized screens (user interfaces) as found on the preferred embodiment of present invention, wherein the user is given a three step overview of the sign-up process: (1) linking a spending account to collect round-ups (i.e. a credit or debit account); (2) setting up a funding source (i.e. a deposit account); and (3) setting up an investment account. Unless otherwise indicated below, the registration is performed step-by-step wherein users are not allowed to skip any steps, or perform the steps out of sequence. Relevant error and informational screens are intermittently displayed throughout the sign-up process as needed and/or required (not shown).

FIG. 4 is an example of the computerized screens as found on the preferred embodiment of present invention, wherein the user is guided through step 1: linking a spending account to collect round-ups (i.e. a spending account, namely a debit or credit card account). In this step, the user selects his or her lender's name (results may be automatically displayed) as well as the USER'S CREDENTIALS (i.e. log-on credentials for that lending institution). Moreover, to the extent that a lending institution requires a third credential (i.e. verification codes and/or pin number), a user is afforded the opportunity to input that as well. Finally, once the USER'S CREDENTIALS are verified, the user is provided a final confirmation screen. The preferred embodiment of present invention may be linked to additional spending accounts in later set-up screens (not shown).

FIG. 5 is an example the computerized screens as found on the preferred embodiment of present invention, wherein the user is guided through step 2: setting up a funding source (i.e. a deposit account). In this step, the user inputs the account number and routing number to a valid checking account. Moreover, the user is likewise prompted to input his or her debit card information (name on card, card number, expiration date, and billing zip code). To the extent that this information is duplicative of step 1 (i.e. the spending account is a debit card linked to a checking account), this second step may be skipped. In addition, the user is given the opportunity to fund his or her account in the amount of $0 to $500, from a debit card or withdrawal from a checking account. Finally, once the USER'S CREDENTIALS are verified, the user is provided a final confirmation screen. The preferred embodiment of present invention may be linked to additional funding sources in later set-up screens (not shown).

FIG. 6 is an example of the computerized screens as found on the preferred embodiment of present invention, wherein the user is guided through step 3: setting up an investment account. In this step, the user inputs certain personal information, including without limitation, his/her name, contact information, date of birth, social security number, and other pertinent details. Finally, once the user's fulfills such information, the user is provided a final confirmation screen. The preferred embodiment of present invention may be linked to additional investment accounts in later set-up screens (not shown).

FIG. 7 is an example of a computerized screen as found on the preferred embodiment of present invention, wherein the user's menu screen and options are shown. Specifically, the menu screen provides a gateway to the user's account home page, investment status page (identified as Past-Present-Future), round-ups transactional ledger, add funds screen, and investment calculator. In addition, the user are a number of links that provide the user access to his/her accounts, investment history, investment allocations, referral programs. Finally the menu screen allows the user to adjust his/her application's settings as well as logout.

FIG. 8 is an example of the computerized screens as found on the preferred embodiment of present invention, wherein the home screen is provides information related to the user's account balance (current value, estimated future value, and recent changes), total round-ups (invested and “waiting” to be transferred from the Digital Queue), and total investment gain. In addition, the home screen provides the user the option of immediately adding funds sufficient to meet the threshold to invest.

FIG. 9 is an example of four computerized screens as found on the preferred embodiment of present invention, wherein the user is provided discrete details related to his/her current and past purchases (e.g., restaurants, cafes, retailers, etc.), and the relevant round-up amount(s) related thereto. The user is further provided a color-coded icon adjacent to the round-up amount to indicate whether the round up is new, approved for transfer, committed to an investment, invested, or otherwise rewarded (rewards are typically provided by the invention operator for marketing purposes, such as successful referrals and/or other milestones achieved). Moreover, when a user decides that a round-up will take place manually, the user is given discretion to approve or disapprove a specific round-up from occurring, all before a transfer to an investment account takes place. Depending on the quantity of transactions, users may scroll through a graphs or a list of data, view such on multiple pages, or filter results based on certain metrics, such as date ranges, transaction amounts, vendor types, or vendor names (not shown). Transactional histories may be refreshed manually (e.g., depressing a button, gesturing such as by “pulling down” a menu, etc.) or automatically (e.g., opening the application, scheduled downloads, or by push alert), as is most suitable to the USER DEVICE or as configured by the user in a subsequent setting screen (not shown).

FIG. 10 is an example of two computerized screens as found on the preferred embodiment of present invention, wherein the user is given a tabular as well as graphical representation of his/her round-ups in the past, present, as well as those predicted in the future. Future expenses may be based on purchasing behavior and/or based on user-inputted transactions, whether recurring or singular in nature. Depending on the quantity of transactions, users may scroll through a graphs or a list of data, view such on multiple pages, or filter results based on certain metrics, such as date ranges, transaction amounts, vendor types, or vendor names (not shown). Transactional histories may be refreshed manually (e.g., depressing a button, gesturing such as by “swiping,” etc.) or automatically (e.g., opening the application, scheduled downloads, or by a data “push,” etc.), as is most suitable to the USER DEVICE or as configured by the user in a subsequent setting screen (not shown).

FIG. 11 is an example of three computerized screen as found on the preferred embodiment of present invention, wherein the user is given a tabular as well as graphical representation of his/her portfolio of investments. The user may view detailed information related to a specific investment, or review information related to other qualified investments available, as well as view market indexes (Dow, S&P, etc.). Moreover, gains are color coded in green, and losses in red. Depending on the gravity of the gain or loss, the shades of green and red increase/decrease correspondingly.

FIG. 12 is an example of a computerized screen as found on the preferred embodiment of present invention, wherein the user is shown, both in numerical as well as graphical formats, the estimated value of his/her investments over time. The user may change his/her assumptions, as well as given a synopsis of how the estimated future values are derived (sample estimated future value option and confirmation screens also shown).

FIG. 13 is an example several computerized screens as found on the preferred embodiment of present invention, wherein the user is afforded the opportunity to make either a one-time investment or automatic periodic investments (daily, weekly, monthly, etc.). The user may investment pre-selected or user-defined amounts into his/her investment account. In the preferred embodiment, a user is always given a final opportunity to confirm additions to his/her investment account.

FIG. 14 is an example of two computerized screens as found on the preferred embodiment of present invention, wherein the user is afforded the opportunity to make user-defined withdrawals from his/her investment accounts. In the preferred embodiment, a user is always given a final opportunity to confirm withdrawals from his/her investment account.

For the purposes of this disclosure, it is assumed that the user has already signed-up to use the system (established user names, passwords, etc.), as well as connected his/her FINANCIAL DATASETS (i.e. BANK DATA, CREDIT CARD DATA, INVESTMENT DATA, etc.) on the relevant application on the USER DEVICE, including by inputting any relevant USER DATA. These steps, while important, are sufficiently described in the “Preferred User Interface” section supra as well as FIGS. 2-6. Accompanying methodologies to (a) establish a USER'S CREDENTIALS and (b) connect to external data stores (e.g., via proprietary database connectors), while varied, are well known and appreciated by those with ordinary skill in the art, and thus, will not be described herein.

As shown in FIG. 15, the preferred method for creating excess funds from retail transactions and apportioning those funds into investments involves the following steps: (a) single account virtual aggregation 200; (b) a threshold triggered single user ACH 300; (c) batch user aggregation for investing 400; and finally (d) providing the user with information related to his/her savings and investments in the form of a scrolling timeline of round-ups 500.

As shown in FIG. 16, the preferred method for single account virtual aggregation 200 and Threshold Triggered Single User ACH 300, commences with the user authenticating himself/herself on the system from a network-enabled User Application 210 on the USER DEVICE. Through the User Application 210, the user authorizes the CENTRAL COMPUTER 220 to access data stores for the user's Credit Card Company 230, which contains records of the User's Transactions 240 (i.e. CREDIT CARD DATA). The User's Transactions 240 in a spending account are returned, usually through the user's Credit Card Company 230, to the CENTRAL COMPUTER 220, as a list of transactions. By way of example, a hypothetical Mrs. Adams's CREDIT CARD DATA might return the following ledger of transactions:

Transaction Date Name Amount Type Category Jan. 1, 2013 Starbucks −$4.15 Debit Coffee Shop Jan. 2, 2013 Albertson's −$25.09 Debit Groceries Jan. 2, 2013 Check $250.00 Credit Unspecified Jan. 2, 2013 Macy's −$44.12 Debit Retail Jan. 3, 2013 Bank of America −$4.00 Debit Bank Fee Jan. 3, 2013 Starbucks −$4.15 Debit Coffee Shop Jan. 4, 2013 Arco −$61.01 Debit Gasoline Jan. 4, 2013 Starbucks −$4.15 Debit Coffee Shop Jan. 5, 2013 [Operator] −$5.00 Debit Investment Most users are anticipated to use a credit card as the source of their primary spending account. However, it is important to note that a User's Transactions 240, are not necessarily limited to a Credit Card Company 230, and may be a bank (debit card spending), a prepaid charge card, proprietary credit account, rewards program or the like. In short, the source of such information is where the User's spending account(s) reside.

Because some of the User's Transactions 240 may not be conducive to “round-ups,” the CENTRAL COMPUTER 220 may process all transactions through a Filter 250, eliminating those undesirable entries. Examples of undesirable ledger entries might include user deposits, third party credits, bank fees, and/or transactions by the invention's operator (which could lead to indefinite loop problems during round-ups). Thus, the CENTRAL COMPUTER 220 may return an abridged list of transactions to its internal databases (i.e. the Filtered Transaction 260), which are later transmitted to the Digital Queue 270 and/or User Application 210. Continuing with Mrs. A's example above, the Filtered Transactions 260 would yield:

Transaction Date Name Amount Type Category Jan. 1, 2013 Starbucks −$4.15 Debit Coffee Shop Jan. 2, 2013 Albertson's −$25.09 Debit Groceries Jan. 2, 2013 Macy's −$44.12 Debit Retail Jan. 3, 2013 Starbucks −$4.15 Debit Coffee Shop Jan. 4, 2013 Arco −$61.01 Debit Gasoline Jan. 4, 2013 Starbucks −$4.15 Debit Coffee Shop

The Filter 250 could employ any number of proprietary or readily-available filtering technologies. In the preferred method, the Filter 250 might simply eliminate records where accompanying transactional metadata meets certain criteria (e.g., transaction type=credit, or category=Bank Fee). Alternatively, each vendor's name may be cross-referenced against a database residing on the CENTRAL SERVER, thereby eliminating undesirable ledger entries (e.g., name=Bank of America, or amount >$0.00).

Assuming that the user elected to automatically round-up all transactions, the list of Filtered Transactions 260 would be passed along to the Digital Queue 270 wholesale. The Digital Queue would compute the difference between the transaction amount (say $4.15) and the next dollar (say $5.00), leading to a queue of that differential amount. For Example, Mrs. Adams first transaction (Starbuck's at $4.15) would be listed in the Digital Queue 270 along with the roundup of $0.85 (i.e. the difference between $5.00 and $4.15). In other words, once the each transaction is intercepted in the CENTRAL COMPUTER 220, with undesired results omitted (a function of Filter 250 leading to Filtered Transactions 260), a process rounds-up each remaining transaction in the Filtered Transactions 260 to the next dollar amount and “sets-aside” each amount of payment that is to be transferred at a later point in time (i.e. maintained in the Digital Queue 270). All information in the Digital Queue 270, would be returned to the CENTRAL COMPUTER 220, and in turn, to the User Application 210. Continuing with the example of Mrs. Adams, her Digital Queue 270 and the data returned to the User Application 210 would appear as follows:

Digital Total Amount Date Name Amount Queue Queued Jan. 1, 2013 Starbucks −$4.15 $0.85 $0.85 Jan. 2, 2013 Albertson's −$25.09 $0.91 $1.76 Jan. 2, 2013 Macy's −$44.12 $0.88 $2.64 Jan. 3, 2013 Starbucks −$4.15 $0.85 $3.49 Jan. 4, 2013 Arco −$61.01 $0.99 $4.48 Jan. 4, 2013 Starbucks −$4.15 $0.85 $5.33

However, if the user has elected to manually select which transactions in the Filtered Transactions 260 to round-up, then all Filtered Transactions 260 are first returned to the User Application 210 (via the CENTRAL COMPUTER 220). At which point, the user would select which transactions to round-up in the Digital Queue 270. Continuing with the example of Mrs. Adams, let's assume she decided to round-up luxury items only. Her Digital Queue 270 would appear as follows:

Round Digital Total Amount Up? Date Name Amount Queue Queued YES Jan. 1, 2013 Starbucks −$4.15 $0.85 $0.85 NO Jan. 2, 2013 Albertson's −$25.09 — $0.85 YES Jan. 2, 2013 Macy's −$44.12 $0.88 $1.73 YES Jan. 3, 2013 Starbucks −$4.15 $0.85 $2.58 NO Jan. 4, 2013 Arco −$11.01 — $2.58 YES Jan. 4, 2013 Starbucks −$4.15 $0.85 $3.43

Subsequently, these round-up amounts are queued up (i.e. aggregated) for electronic transfer into an investment fund at a later point in time, either (a) once the aggregate amount meets a threshold specified in the ACH Trigger 310 and/or (b) upon instruction by the user.

In the first condition, once the total amount queued in the Digital Queue reaches a minimum user-defined threshold set in the ACH Trigger 310, then an instruction is sent to the User's Bank 320 (i.e. containing the funding source) to transfer an amount equal to the total amount in the Digital Queue 270 into the user's Surplus Account 330. Concurrently, a corresponding amount in the Digital Queue would reduce upon confirmation of a successful transfer. By way of example, let's assume that Mrs. Adams set her trigger to $5.00. Under this scenario, the ACH Trigger 310 would transfer $5.33 on Jan. 4, 2013, if Mrs. Adams automatically rounded up all transactions (see paragraph 80, supra), and her Digital Queue would be reduced accordingly ($5.33-$5.33=$0.00). However, if she elected to manually select which transactions to round-up, then her Digital Queue 270 would remain at $3.43 on the same date (see paragraph 81, supra).

In the second condition, a user may elect to “add funds” to the Digital Queue 270 at any time, all without engaging in another retail transaction. This is ordinarily accomplished by adding an amount equal to the difference between the total amount queued in the Digital Queue 270 and the threshold limit specified in the ACH Trigger 310 (and/or CENTRAL COMPUTER 220). Such action would effectuate an ACH Trigger 310, wherein an instruction is sent to the User's Bank 320 (i.e. containing the funding source) to transfer the total amount in the Digital Queue 270 into the user's Surplus Account 330. Consider again the example of Mrs. Adams who (a) manually selected which transactions to round-up; (b) set her trigger to $5.00; and (c) thus, the total amount held in her Digital Queue 270 was $3.43 (see paragraph 81, supra). Instead of waiting for future transactions to accrue, she could elect to immediately add $1.57 to her Digital Queue 270, and thus triggering an ACH of $5.00 from her Bank 320 to her Surplus Account 330. Thereafter, a corresponding amount would be both added and reduced from her Digital Queue 270 (i.e. $3.43+$1.57-$5.00=$0.00).

As shown in FIG. 17, the preferred method for Single Account Virtual Aggregation 200, could be further explained in the logic diagram shown. Process 2000 monitors any transaction done through an approved gateway (starting block 2010) and intercepts the transmitted information (action block 2020). Each transaction is automatically filtered (action block 2030) into two categories: acceptable transactions (not shown) and discarded transactions (block 2035). If the user has automated round-ups (action block 2040), each transaction is rounded up (action block 2050), and placed in the Digital Queue 2070. If the user has not automated round-ups (action block 2040), then the user (action block 2060) must select which transaction are rounded-up (action block 2050) and placed in the Digital Queue 2070, or otherwise declined and discarded (block 2035).

As shown in FIG. 18, the preferred method for Threshold Triggered Single User ACH 300, could be further clarified in the logic diagram shown. Process 3000 monitors the Digital Queue (starting block 3010) and determines if there are sufficient funds (action block 3020) in the user's account to transfer funds (in other words, if the threshold in the ACH Trigger 310 has been met). If so, funds are transferred into the user's surplus account (action block 3060). If not, the user is given the opportunity to modify his/her investment (action block 3030), wherein the user may add funds (action block 3040) sufficient to trigger a transfer (action block 3060). However, if the user does not modify his/her investment, the virtual funds are held (action block 3050) and remains in the Digital Queue (action block 3010) awaiting future transfer.

As shown in FIG. 19, the preferred method for pooling aggregations for omnibus investments 400, commences with pooling all surplus funds transferred via ACH form all users 410 into a user-approved, omnibus investment account usually managed by the invention operator (and/or his designee). Users may either purchase or sell one or more pre-qualified investments offered by the invention's operators (an alternative process may allow for investment in any investment worldwide, whether listed on a publically-traded exchange, OTC investment, or offered through private placement). The aggregation of all users purchase/sale requests 420 are batched periodically (e.g., hourly, daily, weekly, etc.) in bulk purchases 430 and bulk sales 440 through a correspondent institution 450 (e.g., bank, investment house, brokerage, etc.). Funds transfers and investment holdings are generally made and held in the Operator's account 460, although not necessarily limited thereto. Thereafter, corresponding deductions from user surplus accounts as well as apportionment of the investments are virtually divided, pro-rata, in the CENTRAL COMPUTER 470, and displayed on each user's application 480 on the USER DEVICE.

Referring back to FIG. 15, the final step in the preferred method for creating excess funds from retail transactions and apportioning those funds into investments involves providing the user with information related to his/her savings and investments in the form of a scrolling timeline of round-ups 500. Accompanying methodologies to provide historical ledgers of past transactions (i.e. here embodied as a scrolling timeline of round-ups), while varied, are well known and appreciated by those with ordinary skill in the art, and thus, will not be described herein. Notwithstanding, an exemplary embodiment of a user interface of a scrolling timeline of round-ups may be seen in FIGS. 9 and 10.

In addition to the scrolling timeline of round-ups 500, the user is provided both summary and detailed information related to his/her pro rata share of investments (not shown in FIG. 19). Such information may generally include historical purchases and sales information, provided in both tabular and graphical formats, which may be scrolled or “paged over” if the quantity of information requires. In addition, the preferred method may further provide publically-available information related to the investments, including pricing trends (usually shown as a line graph), percentage changes in pricing, financial information (e.g., 52 week price range, YTD return, etc.), financial ratios and metrics (e.g., P/E, EBITDA, etc.), and other notable information that may be of interest to an investor. Moreover, the user may be provided with current values of his/her investment(s) which is usually a simply calculated by using a standard current value formula, such as:

Σ(Current price×number of shares)_(n)

-   -   or net present value (NPV) of an annuity-type investment.         Finally, in the preferred method, the user may be provided with         estimated future values (EFV) of his/her investment(s) which are         based on historical returns. Historical returns are calculated         by looking at the asset classes that form the portfolio and         studying their historical co-variances, variances, and returns.         Accompanying methodologies to provide historical ledgers and         charts of past transactions, real-time investment information,         as well as present values and estimated future value         computations, while varied and nuanced, are well known and         appreciated by those with ordinary skill in the art, and thus,         will not be described in great detail herein. Notwithstanding,         an exemplary embodiment of a user interface of his/her         investment information may be seen in FIGS. 11 and 12.

In an alternative embodiment, and for either actual or hypothetical purposes, estimated future values may be computed using a other future (FV) calculations, such as:

(present value)×((1+r)^(n)−1)/r)

In so doing, the user may select either an automatic calculation of the rate of return (r) which may be based on the user's past performance, or the user may select predefined rates of return (e.g., 2%, 7%, 10.4%, etc.). The time period (n) are set at intervals of many years in the future (e.g., 10 years, 20 years, etc.).

Any of the above-described processes and methods may be implemented by any now or hereafter known computing device. For example, the methods may be implemented in such a device via computer-readable instructions embodied in a computer-readable medium such as a computer memory, computer storage device or carrier signal.

The preceding described embodiments of the invention are provided as illustrations and descriptions. They are not intended to limit the invention to precise form described. In particular, it is contemplated that functional implementation of invention described herein may be implemented equivalently in hardware, software, firmware, and/or other available functional components or building blocks, and that networks may be wired, wireless, or a combination of wired and wireless. Other variations and embodiments are possible in light of above teachings, and it is thus intended that the scope of invention not be limited by this Detailed Description, but rather by Claims following. 

What is claimed is:
 1. A computer-implemented system comprising one or more processors for managing electronic transactions between a first terminal, in electronic communication with a payment gateway server, and a consumer communication device, configured to create an electronic payment gateway with the first terminal, wherein the consumer communication device is operatively coupled to a computer program product, the computer program product having a computer-usable medium having a sequence of instructions which, when executed by a processor, causes said processor to: receive transaction data to process a first transaction from a plurality of transactions, the transaction data comprising at least one of a transaction descriptor or a transaction value associated with the first transaction; filter the transaction data by applying a filtering parameter to at least one of the transaction descriptor or the transaction value; prevent application of a round up process to the first transaction based on the filtering, in response to the determining that the first transaction is not conducive to the round up process, thereby preventing an error state in execution of logic code by at least one processor configured for applying the round up process to the first transaction; and apply the round up process to a second transaction, in response to determining that the transaction is conducive to the round up process, the round up process comprising determining a difference between a numerical value of the second transaction and another numerical amount that is a rounded up integer value of the numerical value.
 2. The computer-implemented system of claim 1, wherein an amount of currency is transferred from an account of the user to another account, in response to the application of the round up process to the second transaction.
 3. The computer-implemented system of claim 1, wherein an electronic ledger is created for one or more transactions selected from the plurality of transactions for the purpose of applying the round up process.
 4. The computer-implemented system of claim 3, wherein the electronic ledger includes at least one descriptor specific to a selected transaction.
 5. The computer-implemented system of claim 4, wherein the at least one descriptor is at least one of: a date when the selected transaction occurred, a name associated with the selected transaction, the actual numerical amount, a type of the selected transaction, and a category specific to the selected transaction.
 6. The computer-implemented system of claim 1, wherein the one or more processors monitor a database for the plurality of the transactions when a software application is activated on a user device.
 7. The computer-implemented system of claim 6, wherein the one or more processors monitor a database for the plurality of the transactions when the software application is refreshed by a swipe on a graphical user interface of the user device.
 8. The computer-implemented system of claim 1, wherein the one or more processors monitor a database for the plurality of the transactions periodically.
 9. The computer-implemented system of claim 1, wherein a database is configured to be maintained by a financial institution that provides an instrument to the user for performing the plurality of transactions.
 10. The computer-implemented system of claim 1, wherein the one or more processors transmit a difference for a plurality of selected transactions to a graphical user interface for display in real-time.
 11. A computer-implemented system for managing transactions between a point of sale terminal, in electronic communication with a payment gateway server, and a consumer communication device operatively coupled to a computer program product having a computer-usable medium having a sequence of instructions which, when executed by a processor, causes said processor to: receive transaction data to process a first transaction from a plurality of transactions, the transaction data comprising at least one of a transaction descriptor or a transaction value associated with the first transaction; filter, using a filter, the transaction data by applying a filtering parameter to at least one of the transaction descriptor or the transaction value; prevent application of a rounding process to the first transaction based on the filtering, in response to the determining that the first transaction is not conducive to the rounding process, thereby preventing an error state in execution of logic code by at least one processor configured for applying the rounding process to the first transaction; and apply the rounding process to a second transaction, in response to determining that the transaction is conducive to the rounding process, the rounding process comprising determining a difference between a numerical value of the second transaction and another numerical amount that is a rounded integer value of the numerical value.
 12. The computer-implemented system of claim 11, wherein an amount of currency is transferred from an account of the user to another account, in response to the application of the rounding process to the second transaction.
 13. The computer-implemented system of claim 11, wherein an electronic ledger is created for one or more transactions selected from the plurality of transactions for the purpose of applying the rounding process.
 14. The computer-implemented system of claim 11, wherein the rounding process is a round up process.
 15. The computer-implemented system of claim 11, wherein the rounding process applied to the second transaction results in the numeric value of the second transaction being rounded to a numeric value equal to an integer value greater than the numeric value of the second transaction.
 16. The computer-implemented system of claim 11, wherein the rounding process applied to the second transaction results in the numeric value of the second transaction being rounded to a numeric value equal to an integer value less than the numeric value of the second transaction. 